Image-based tracking

ABSTRACT

A method of image-tracking by using an image capturing device. The method comprises: performing an image-capture of a scene by using an image capturing device; and tracking movement of the image capturing device by analyzing a set of images by using an image processing algorithm.

TECHNICAL FIELD

The technology relates to the field of image-based navigation.

BACKGROUND

In areas without a clear view of the sky, e.g. tunnels or forests, GPS devices face the challenging task of maintaining accurate localization, due to the lack of reception from the GPS satellites. We present an application, which we call “ground tracking”, that can recover the 3D location of an image capturing device. This image capturing device, which can be in any orientation, captures images and uses a combination of statistics and image processing algorithms to estimate its 3D trajectory.

SUMMARY

This Summary is provided to introduce a selection of concepts that are further described below in the Detailed Description. This Summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

A method of image-tracking is provided. The method comprises: (A) performing an image-capture of a scene by using an image capturing device; and (B) tracking movement of the image capturing device by analyzing a set of images.

DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and form a part of this specification, illustrate embodiments of the technology and, together with the description, serve to explain the principles below:

FIG. 1 depicts an apparatus for image-tracking in accordance with an embodiment of the present technology.

FIG. 2 is a flow chart of a method of image-tracking in accordance with an embodiment of the present technology, wherein the depth data of the scene is obtained by pre-surveying the scene.

FIG. 3 illustrates a flow chart of a method of image-tracking in accordance with an embodiment of the present technology, wherein the depth data of the scene is obtained by using a range measurement device.

FIG. 4 is a diagram illustrates the taking by the image capturing device, an image of a scene.

FIG. 5 depicts a diagram illustrating the image capturing device 2D motion calculated by using the image processing algorithm in accordance with an embodiment of the present technology.

FIG. 6 is a diagram illustrating the image capturing device height motion calculated by using the image processing algorithm in accordance with an embodiment of the present technology.

FIG. 7 depicts a diagram illustrating the image capturing device total rotation angels (yaw, pitch and roll) calculated by using the image processing algorithm in accordance with an embodiment of the present technology.

DETAILED DESCRIPTION

Reference now is made in detail to the embodiments of the technology, examples of which are illustrated in the accompanying drawings. While the present technology will be described in conjunction with the various embodiments, it will be understood that they are not intended to limit the present technology to these embodiments. On the contrary, the present technology is intended to cover alternatives, modifications and equivalents, which may be included within the spirit and scope of the various embodiments as defined by the appended claims.

Furthermore, in the following detailed description, numerous specific-details are set forth in order to provide a thorough understanding of the presented embodiments. However, it will be obvious to one of ordinary skill in the art that the presented embodiments may be practiced without these specific details. In other instances, well known methods, procedures, components, and circuits have not been described in detail as not to unnecessarily obscure aspects of the presented embodiments.

FIG. 1 is a block diagram 10 that illustrates an apparatus for image-tracking 22 in accordance with an embodiment of the present technology.

In an embodiment of the present technology, the image-tracking apparatus 22 further comprises: an image capturing device 12 configured to perform an image-capture of a scene 20 in a software mode (SW) further comprising a memory 24 loaded with an image processing algorithm 25, and a general purpose processor (or a Digital Signal Processor, or a Graphic Processing Unit, etc) 26 configured to analyze the set of images by enabling the image processing algorithm 25.

In an embodiment of the present technology, the image-tracking apparatus 22 further comprises: an image capturing device 12 configured to perform an image-capture of a scene 20 in a hardware mode (HW) further comprising an ASIC chip (or FPGA chip) 27 (in analog or digital modes) configured to analyze the set of images by implementing in hardware the image processing algorithm 25.

The image capturing device 12 is selected from the group consisting of: {a digital camera; a digital video camera; a digital camcorder; a stereo digital camera; a stereo video camera; a motion picture camera; a television camera; and a depth camera}.

In an embodiment of the present technology, the image capturing device 12 is a light-tight box in which an image of a scene 20 is formed by a pinhole or lenses 16 at a sensor plate 32. Still video and digital cameras store the images in a solid-state memory 28, or on magnetic media or optical disks 28.

Motion picture or cine cameras record movement at regular intervals in a series of frames. Television and video cameras record movement electronically for broadcast and storage on magnetic media or optical disks. Camcorders are video cameras which contain both the image sensor and recording media in a single unit.

Except for pinhole cameras, which focus the image on the film through a tiny hole, all other cameras use lenses 16 for focusing. The focal length of lenses, i.e., the distance between the rears of the lenses (when focused on infinity) the imaging device, determines the angle of view, or field of view (FOV) 18 and the size of objects as they appear on the imaging surface-sensor plate 32. The image is focused on that surface by adjusting the distance between the lenses and the surface.

In an embodiment of the present technology, the lens 16 further comprises regular rectilinear lens. Rectilinear lens is a lens in which straight lines are not substantially curved or distorted.

In an embodiment of the present technology, the lens 16 further comprises a fisheye lens. A fisheye lens is a wide-angle lens that takes in an extremely wide, hemispherical image. Fisheye lenses are often used to shoot broad landscapes. Fisheye lenses achieve extremely wide angles of view by forgoing a rectilinear image, opting instead for a special mapping (for example: equisolid angle), which gives images a characteristic convex appearance.

In an embodiment of the present technology, the lens 16 further comprises custom-calibrated lenses.

In an embodiment of the present technology, the image capturing device 12 further comprises a display 34 further comprising an optical display, a liquid crystal display (LCD), or a screen.

In an embodiment of the present technology, the image capturing device 12 further comprises a stereo digital camera. A stereo camera is a type of camera with two or more lenses. This allows the camera to simulate binocular vision, and therefore gives it the ability to capture three-dimensional images, a process known as stereo photography. Stereo cameras may be used for making stereo views and 3D pictures for movies, or for range imaging. 3-D Images Ltd., located in UK, produces a 3-D Digital Stereo camera—a fully automatic, time synchronized, digital stereo camera. Point Grey Research Inc., located in Canada produces binoculars or multiple array cameras that can provide full field of view 3 D measurements ion an unstructured environment.

The fundamental element of an image of an object is the pixel which describes a single point of color or a grayscale.

Each pixel contains a series of numbers which describe its color or intensity. The precision to which a pixel can specify color is called its bit or color depth. The more pixels an image contains, the more detail it has the ability to describe.

Since a pixel is just a logical unit of information, it is useless for describing real-world dimensions unless you also specify their size. The term pixels per inch (PPI) was introduced to relate this theoretical pixel unit to real-world visual resolution.

“Pixels per inch” (PPI) is a very straightforward term. It describes just that: how many pixels an image contains per inch of distance in the horizontal and vertical directions.

A “megapixel” is simply a unit of a million pixels. A digital camera may use a sensor array of megapixels (millions of tiny pixels) in order to produce an image. When the camera's shutter button is pressed and the exposure begins, each of these pixels has a “photo site” which stores photons. Once the exposure finishes, the camera tries to assess how many photons fell into each. The relative quantity of photons in each cavity are then sorted into various intensity levels, whose precision is determined by bit depth (0-255 for an 8-bit image).

Each cavity is unable to distinguish how much of each color has fallen in, so the above description would only be able to create grayscale images. One method used to extend digital sensors to capture color information is to filter light entering each cavity allowing the sensor to distinguish between Red (R), Green (G) and Blue (B) lights.

In an embodiment of the present technology, the distance from an object point 30 on the scene 20 depth to the image-based tracking device 22 is determined by using a range measuring device 14 selected from the group consisting of: {a point laser beam; a sonar; a radar; a laser scanner; and a depth camera}.

A point laser beam range measuring device 14 can be implemented by using a blue solid-state lasers, red diode lasers, IR lasers which maybe continuously illuminated lasers, or pulsed lasers, or sequenced lasers.

A laser scanner range measuring device 14 can be implemented by using positioning sensors offered by Sensor Intelligence website www.sick.com. For instance, the Laser Scanner Model Name S10B-9011DA having compact housing and robust IP 65 design may be used. This laser scanner has the following data sheet: dimensions: (W×H×D)=102×152×105 mm, the scan angle of 270°, and the switching field range of 10 meters. It has the following functionality: a stand-by mode, a 7-segment input display, an integrated parameter memory in-system, a plug CANopen interface, and low energy consumption.

A sonar range measuring device 14 can be implemented by using active sonar including sound transmitter and a receiver.

Active sonar creates a pulse of sound, often called a “ping”, and then listens for reflections (echo) of the pulse. This pulse of sound is generally created electronically using a sonar projector consisting of a signal generator, power amplifier and electro-acoustic transducer/array, possibly with a beam former. To measure the distance to the scene 20, the time from transmission of a pulse to reception is measured and converted into a range by knowing the speed of sound. The pulse may be at constant frequency or a chirp of changing frequency (to allow pulse compression on reception). Pulse compression can be achieved by using digital correlation techniques.

A radar range measuring device 14 can be implemented by using a transmitter that emits either microwaves or radio waves that are reflected by the scene 20 and detected by a receiver, typically in the same location as the transmitter.

In an embodiment of the present technology, the image capturing device 12 further comprises a depth camera that combines taking images of an object with measuring a distance to the object.

A depth camera can be implemented by using a ZCam video camera that can capture video with depth information. This camera has sensors that are able to measure the depth for each of the captured pixels using a principle called Time-Of-Flight. It gets 3D information by emitting pulses of infra-red light to all objects in the scene and sensing the reflected light from the surface of each object. Depth is measured by computing the time-of-flight of a ray of light as it leaves the source and is reflected by the objects in the scene 20. The round trip time is converted to digital code independently for each pixel using a CMOS time-to-digital converter. According to manufacturer 3DV Systems, the depth resolution is quite good: it can detect 3D motion and volume down to 0.4 inches, capturing at the same time full color, 1.3 megapixel video at 60 frames per second.

In an embodiment of the present technology, referring still to FIG. 1, the image capturing device 12 further comprises a surveying instrument 36 selected from the group consisting of: {a Global Navigation Satellite System (GNSS) surveying system; a laser plane system; and a theodolite}. In this embodiment, the scene 20 is pre surveyed and the scene distance data is used by the image-based tracking device 22 in combination with the set of images to determine the position coordinates of the image-based tracking device 22.

A Global Navigation Satellite System (GNSS) surveying system 36 can be implemented by using a TRIMBLE R8 GNSS system that supports all GPS and GLONASS L1/L2 signals, including the new L2C and coming L5 signals of GPS and has the capacity to track up to 44 satellites.

A Global Navigation Satellite System (GNSS) surveying system 36 can be also implemented by using The Trimble® R7 GNSS System including a high-accuracy GPS receiver and UHF radio combined in one unit. Trimble R7 GNSS can be used for RTK or static surveying. The modular Trimble R7 GNSS System employs a separate antenna: the Trimble Zephyr™ 2 when used as a rover and the Zephyr Geodetic™ 2 when used as a base station. The Trimble GeoExplorer software can be used for different pathfinder scenarios. The Trimble GeoExplorer has the following data sheet: 1 to 3 meter GPS with integrated SBAS; a High-resolution VGA display for crisp and clear map viewing; a Bluetooth and wireless LAN connectivity options; a 1 GB onboard storage plus SD slot for removable cards. It includes Windows Mobile version 6 operating system. It is also implemented as a rugged handheld with all-day battery.

A laser plane surveying system 36 can be also implemented by using a Trimble product-Spectra Precision laser GL 412 and GL 422. The Spectra Precision® Laser GL 412 and GL 422 Grade Lasers are cost-effective, automatic self-leveling lasers that do three jobs—level, grade and vertical alignment with plumb. Both lasers feature a 2-way, full-function remote control so one can make grade changes from anywhere on the jobsite for reduced setup time and faster operation. The GL 412 (single grade) and GL 422 (dual grade) lasers send a continuous, self-leveled 360-degree laser reference over entire work area, and have a wide grade range so they can be used in a variety of slope applications.

A laser plane surveying system 36 can be also implemented by using Apache Horizon laser that emits a continuous self-leveled laser beam that is rotated to create a plane of laser light. This plane extends over a work area up to 1600 foot (500 meter) diameter. The reference plane is sensed by one or more laser detectors that indicate the direction to on-grade.

A theodolite surveying system 36 can be also implemented by using Trimble® S6 DR (direct reflex) Total Station that is cable-free robotic total station and rover. One can choose from active or passive tracking with the Trimble MultiTrack Target. Active tracking allows one to locate and lock on to the correct target.

In an embodiment of the present technology, the method of image-tracking is implemented by using the image-based tracking device 22 of FIG. 1. More specifically, the step (A) is performed by using the image capturing device 12 to perform image-capture of a scene 20, whereas the step (B) of tracking movement of the image capturing device 12 is performed by analyzing a set of images using an image processing algorithm 25.

In an embodiment of the present technology, the step (A) of performing image-capture of the scene 20 is performed in real time by using the image capturing device 12.

In another embodiment of the present technology, the step (A) of performing image-capture of the scene 20 is pre-recorded by using the image capturing device 12.

In an embodiment of the present technology, the step (A) of performing image-capture of the scene 20 further comprises the step (A3) of obtaining a set of depth data of the scene 20 by pre-surveying the scene 20 using the surveying instrument 36 as was fully disclosed above.

In an embodiment of the present technology, the step (B) of tracking movement of the image capturing device 12 is performed by using the image processing algorithm 25.

In an embodiment of the present technology, the image processing algorithm 25 allows implementation of video tracking of the image capturing device 12 by analyzing the set of images it captures.

In an embodiment of the present technology, the image processing algorithm 25 assumes global rigid motion. By parameterizing the global optical flow with the image capturing device's 12 six degrees of freedom, an optimal global transformation between two consecutive frames can be found by solving a non-linear Least-Squares problem.

To perform a rigid global transformation with six degrees of freedom, one need to know the depth of the scene 20. As was fully disclosed above, either the scene 20 is pre-surveyed, or the depth measurements are obtained in real time along with the image-capture from external devices such as point laser beams, depth image capturing devices, a stereo camera rig, etc. . . .

In an embodiment of the present technology, the image processing algorithm 25 matches the optical properties of the pixels by using a frame function.

In an embodiment of the present technology, with the depth information available, the image processing algorithm 25 matches the depth of the two frames (instead of optical properties of the pixels) by redefinition of frame function.

In an embodiment of the present technology, the image processing algorithm 25 can be improved by matching a combination of pixel optical properties and depth information. This can be done by either using a combined cost function, or aiding one process with the other, as fully disclosed below.

In an embodiment of the present technology, the image processing algorithm 25 utilizes several coordinate systems: a stationary reference system; a reference system attached to the image capturing device 12; and a 2D reference system on image capturing device's sensor plane 32.

In the stationary reference system a point 30 in the scene 20 has coordinates x=(x,y,z), the image capturing device 12 is described by 6-vector 38 comprising device's position coordinates x_(ci)=(x_(ci), y_(ci), z_(ci)) and device's orientation coordinates (ψ_(i),θ_(i),φ_(i)) (yaw, pitch and roll) for each i^(th) frame.

In the reference system attached to the image capturing device 12 the same point 30 in the scene 20 has coordinates x_(i)=(x_(i),y_(i),z_(i)) w.r.t. the image capturing device 12.

In the 2D reference system attached to the image capturing device's sensor plane 32 the 2D pixel coordinates of a point in the i^(th) frame is: u=(u _(i) ,v _(i)).

The relation between the stationary 3D system and the image capturing device-attached 3D system is as follows: x _(i)=(x−x _(ci))R _(i),  (Eq. 1) Where

$\begin{matrix} {R_{i} = {\begin{pmatrix} {\cos\left( \Psi_{i} \right)} & {- {\sin\left( \Psi_{i} \right)}} & 0 \\ {\sin\left( \Psi_{i} \right)} & {\cos\left( \Psi_{i} \right)} & 0 \\ 0 & 0 & 1 \end{pmatrix}\begin{pmatrix} {\cos\left( \theta_{i} \right)} & 0 & {\sin\left( \theta_{i} \right)} \\ 0 & 1 & 0 \\ {- {\sin\left( \theta_{i} \right)}} & 0 & {\cos\left( \theta_{i} \right)} \end{pmatrix}\begin{pmatrix} 1 & 0 & 0 \\ 0 & {\cos\left( \varphi_{i} \right)} & {- {\sin\left( \varphi_{i} \right)}} \\ 0 & {\sin\left( \varphi_{i} \right)} & {\cos\left( \varphi_{i} \right)} \end{pmatrix}}} & \left( {{Eq}.\mspace{14mu} 2} \right) \end{matrix}$ is the rotation matrix between two systems.

The relation between the image capturing device-attached 3D coordinates and the 2D pixel coordinates depends on the mapping function m of the image capturing device 12. The mapping function takes 3D coordinates x_(i) in the image capturing device-attached system of the i^(th) frame and maps into a 2D pixel coordinates in the i^(th) frame: u _(i) =m(x _(i)).  (Eq. 3)

The form of the mapping function depends on the type of the lenses. In an embodiment of the present technology, wherein the lenses 16 comprise regular rectilinear lenses (in an inverted pin-hole model), the mapping function m can be derived from the following equations:

$\begin{matrix} \begin{matrix} {u_{i} = {{\frac{f}{S_{u}}\frac{x_{i}}{z_{i}}} - u_{0}}} \\ {{v_{i} = {{\frac{f}{S_{v}}\frac{y_{i}}{z_{i}}} - v_{0}}};} \end{matrix} & \left( {{Eqs}.\mspace{14mu} 4} \right) \end{matrix}$

where f is the image capturing device 12 focal length, S_(u), S_(v) are the pixel width and height. u₀, v₀ are the offsets between the optical center and sensor center.

In another embodiment of the present technology, wherein the lenses 16 comprise orthographic fisheye lenses, the mapping function m can be derived from the following equations:

$\begin{matrix} {{{u_{i} = {{\frac{f}{S_{u}}\frac{x_{i}}{r}} - u_{0}}}v_{i} = {{\frac{f}{S_{v}}\frac{y_{i}}{r}} - v_{0}}};} & \left( {{Eqs}.\mspace{14mu} 5} \right) \end{matrix}$ where r is the distance between the point and the optical center r=√{square root over (x_(i) ²+y_(i) ²+z_(i) ²)}.

In an embodiment of the present technology, the mapping function m can be calibrated and stored in a numeric form.

To find out the reverse of the mapping function: x _(i) =m ⁻¹(u _(i)),  (Eq. 6) one need to know the depth of the object point 30.

In an embodiment of the present technology, as was disclosed above, the scene 20 is pre-surveyed. In this embodiment of the present technology, the depth measurements are made in the 3D stationary reference system z=z(x,y), and do not change from frame to frame.

In an embodiment of the present technology, if a range measuring device 14 is attached to the image capturing device 12, the depth of a scene object point 30 is obtained as a function of pixel location in each frame z_(i)=z_(i)(u_(i)). These measurements are made in the image capturing device-attached 3D reference system.

In an embodiment of the present technology, the range measuring device 14 is implemented by using a number of point lasers. In this embodiment of the present technology, since the number of point lasers are usually far less than the number of pixels, the density of depth measurements for each i-th frame is likely to be much less than the pixels density. The depth for each pixel can be obtained by interpolation among these measurements.

In an embodiment of the present technology, the range measuring device 14 is implemented by using a depth camera such as the Zcam from 3DVsystems. In this embodiment of the present technology, a grid of depth measurements is available with comparable resolution to that of the video frame, so that this grid of depth measurements can be used directly without further treatment.

In an embodiment of the present technology, the range measuring device 14 is implemented by using a stereo camera. A stereo camera allows the extraction of depth info from a number of identified feature points and the rest of the pixels can be done by interpolation.

The relation between two sequential frames f_(i) and f_(j) is built upon the assumption that the same point 30 in the scene 20 produces two pixels of the same intensity in two frames. That is, if u_(i) and u_(j) are pixel locations in f_(i) and f_(j) of the same object point, then f_(i)(u_(i))=f_(j)(u_(j)). Here f_(i)(u_(i)) refers to the pixel intensity at u_(i) in frame f_(i). Under this assumption the relation between two frames is purely a geometrical transformation resulting from the image capturing device's motion.

The image capturing device motion from f_(i) to f_(j) can be represented by δx_(ci→j) and δR_(i→j), which is the relative shift and rotation between frames, or, ξ_(i→j)=(δx_(ci→j), δy_(ci→j), δz_(ci→j), δψ_(i→j), δθ_(i→j), δφ_(i→j)), which is a 6-vector having the six degrees of freedom. If the image capturing device position and attitude at frame f_(i) is known, then solving this relative motion from f_(i) to f_(j) gives us the position and attitude at frame f_(j). In the following we will drop the subscript i→j whenever possible.

The same object point 30 which has coordinates x_(i) in frame f_(i)'s reference system has coordinates x_(j) in frame f_(j)'s reference system, and: x _(j)=(x _(i) −δx _(c))δR.  (Eq. 7)

Therefore in the 2D pixel coordinate systems, the relation between u_(i) and u_(j) is as follows:

$\begin{matrix} {{u_{i}\underset{\rightarrow}{m^{- 1}}x_{i}\underset{\rightarrow}{\xi}x_{j}\underset{\rightarrow}{m}u_{j}},} & \left( {{Eq}.\mspace{14mu} 8} \right) \end{matrix}$ where m is the mapping function. Or simply u _(j) =δP(u _(i)),  (Eq. 9) where δP=m∘ξ∘m⁻¹ represents the combination of three operations.

The task now is to find out the optimal ξ so that the cost function ∫|f _(i)(u)−f _(i)(δP(u))|² du  (Eq. 10) is minimized. This is a well-researched nonlinear least-squares problem. Solving it usually involves linear approximation and iteration. Different linear approximations give rise to different convergence methods, such as Gauss-Newton, steepest-descent, Levenberg-Marquardt descent, etc.

In an embodiment of the present technology, the image processing algorithm 25 is implemented by using Gauss-Newton formulation. To get Gauss-Newton formulation, one may expand

$\begin{matrix} {{f_{j}\left( {\delta\;{P(u)}} \right)} \approx {{f_{j}(u)} + {{\mathbb{d}\xi}{\nabla f_{j}}\frac{{\partial\delta}\;{P(u)}}{\partial\xi}}}} & \left( {{Eq}.\mspace{14mu} 11} \right) \end{matrix}$ ∇f_(j) is the gradient image of frame f_(j),

$\frac{{\partial\delta}\;{P(u)}}{\partial\xi}$ is the Jacobian of the geometrical transformation. Write

$\begin{matrix} {D = {{\nabla f_{j}}\frac{{\partial\delta}\;{P(u)}}{\partial\xi}}} & \left( {{Eq}.\mspace{14mu} 12} \right) \end{matrix}$ as a 6×1 column vector, then one has dξ≈∫(f _(i)(u)−f _(j)(u))D ^(T) du/∫/DD ^(T) du  (Eq. 13)

Since f_(i) is not a linear function of ξ, the (Eq. 13) is being solved by using the following iteration loop routine:

1. Initialize ξ;

2. Calculate δP from ξ, perform transformation on f_(j): f_(j)(u)

f′_(j)(u)=f_(j)(δP(u));

3. Calculate dξ from f_(i), f′_(j), dξ=∫(f _(i)(u)−f′ _(j)(u))D ^(T) du/∫DD ^(T) du

4. Update ξ, dξ

ξ;

5. If dξ is small enough or maximum iteration reached then exit, otherwise loop back to step 2.

In the above routine, with each subsequent iteration f_(j) is getting closer to f_(i) until they are close enough. However, in each iteration the gradient image of f′_(j) has to be recalculated because f′_(j) has been updated in step 2). The other issue is that δP (and hence the Jacobian) depends on the depth measurements z_(j), or, in the case of pre-surveying of depth in the stationary reference system, depends on the depth measurements z and the total image capturing device movement that leads to the frame f_(j):x_(cj), R_(j).

In an embodiment of the present technology, wherein the depth measurements are obtained in the image capturing device-attached reference system (such as laser points, depth camera, stereo rig, etc), more depth measurements are available for frame f_(i) because all previous frames measurements can be transformed to frame f_(i)'s reference system now that x_(ci), R_(i) is known.

In an embodiment of the present technology, whereas the depth of the scene is pre-surveyed in the stationary system, the total movement x_(cj), R_(j) is yet to be solved and thus can only be expressed as functions of x_(ci), R_(i) and ξ when the form of Jacobian is calculated. This not only complicates the form of the Jacobian but also makes the Jacobian iteration-dependent.

In an embodiment of the present technology, the gradient image of f_(i), and the Jacobian at frame f_(i) are calculated while transforming f_(i) in the iterations. Therefore 1) dξ is calculated using ∫|f_(i)(δP⁻¹(u))−f_(j)(u)|²du instead in each iteration, which allows one to use the gradient image of f_(i) and the Jacobian of reverse transformation

$\frac{{\partial\delta}\;{P^{- 1}(u)}}{\partial\xi}$ is evaluated at frame f_(i), both of which need to be calculated only once. 2) The accumulated ξ, and δP, will be applied on f_(j) to bring it close to f_(i), so as to avoid any transformation on f_(i).

So after redefining

$D = {{\nabla f_{i}}\frac{{\partial\delta}\;{P(u)}}{\partial\xi}}$ which is evaluated at frame f_(i), the image processing algorithm 25 is revised as follows:

1. Initialize ξ;

2. Initialize

$D = {{\nabla f_{i}}\frac{{\partial\delta}\;{P(u)}}{\partial\xi}}$ at frame f_(i);

3. Calculate δP from ξ perform transformation on f_(j): f_(j)(u)

f′_(j)(u)=f_(j)(δP(u));

4. Calculate dξ from f_(i),f′_(j), dξ=∫(f _(i)(u)−f′ _(j)(u))D ^(T) du/∫DD ^(T) du;

5. Update ξ, dξ

ξ;

6. If dξ is small enough or maximum iteration reached then exit, otherwise loop back to step 3.

The depth for each pixel in f′_(j) is needed to compute δP(u) in step 3). Since f′_(j) is the best estimate of f_(i) at the moment, the simplest choice is to use depth for pixels in f_(i) instead.

In an embodiment of the present technology, the convergence of the iterations depends on how “smooth” the gradient image is. If the gradient image varies on a much smaller scale than the image displacement resulted from image capturing device movement between two frames, the loop may not converge. Therefore the two frames are smoothed first before being fed into the above loop. After an approximate ξ is found from smoothed frames, the smoothing can be removed or reduced and a more accurate ξ can be obtained with the previous ξ as a starting point.

Thus, in an image iteration pyramid the higher level is more heavily smoothed while the bottom level is the raw image without smoothing. From top to bottom of the image pyramid ξ is refined as follows:

1. Initialize ξ

2. Construct image pyramids of f_(i) and f_(j) if not already available

3. From top to bottom for each level of the pyramid

-   -   3.1 initialize

$D = {{\nabla f_{i}}\frac{{\partial\delta}\;{P(u)}}{\partial\xi}}$ at frame f_(i);

-   -   3.2 calculate dξ from f_(i), f′_(j),         dξ=∫(f _(i)(u)−f′ _(j)(u))D ^(T) du/∫DD ^(T) du;     -   3.3 update ξ, dξ         ξ;     -   3.4 perform transformation on f_(j): f_(j)(u)         f′_(j)(u)=f_(j)(δP(u));     -   3.5 if dξ is small enough or maximum iteration reached then         exit, otherwise loop back to step 3.2.

The explicit form of δP(u_(i)) depends on the mapping function m. Even with a given m the form of δP(u_(i)) is not unique. In an embodiment of the present technology when the lenses 16 comprises the rectilinear lenses and when pre-surveyed depth z is available, one may choose:

$\begin{matrix} {{\left( {\overset{\sim}{u},\overset{\sim}{v},\overset{\sim}{w}} \right) = {\left( {u_{i},1} \right)\left( {1 - {\frac{R_{i}^{T}\left( {3,\text{:}} \right)}{z - z_{c\; i}}\delta\; x_{c}}} \right)\delta\; R}},{{\delta\;{P\left( u_{i} \right)}} = \left( {\frac{\overset{\sim}{u}}{\overset{\sim}{w}},\frac{\overset{\sim}{v}}{\overset{\sim}{w}}} \right)}} & \left( {{Eqs}.\mspace{14mu} 14} \right) \end{matrix}$ where R_(i) ^(T)(3, :) is the transpose of the third row of the total rotation matrix R_(i) at frame f_(i). It is the unit vector in the z direction, expressed in frame f_(i)'s image capturing device-attached reference system.

$\begin{matrix} {{D = \begin{pmatrix} {{- a}\; f_{i,u}} \\ {{- a}\; f_{i,v}} \\ {a\left( {{u\; f_{i,u}} + {v\; f_{i,v}}} \right)} \\ {{v\; f_{i,u}} - {u\; f_{i,v}}} \\ {{{- \left( {1 + u^{2}} \right)}f_{i,u}} - {u\; v\; f_{i,v}}} \\ {{u\; v\; f_{i,u}} + {\left( {1 + v^{2}} \right)f_{{i,v}\;}}} \end{pmatrix}}{a = {\left( {u,1} \right)\frac{R_{i}^{T}\left( {3,\text{:}} \right)}{z - z_{c\; i}}}}} & \left( {{Eq}.\mspace{14mu} 15} \right) \end{matrix}$

In an embodiment of the present technology, when the depth measurements are made in the image capturing device-attached system (z_(i) is known), one may choose

$\begin{matrix} {{\left( {\overset{\sim}{u},\overset{\sim}{v},\overset{\sim}{w}} \right) = {\left( {\left( {u_{i},1} \right) - {\frac{1}{z_{i}}\delta\; x_{c}}} \right)\delta\; R}}{{\delta\;{P\left( u_{i} \right)}} = \left( {\frac{\overset{\sim}{u}}{\overset{\sim}{w}},\frac{\overset{\sim}{v}}{\overset{\sim}{w}}} \right)}{and}} & \left( {{Eqs}.\mspace{14mu} 16} \right) \\ {{D = \begin{pmatrix} {{- a}\; f_{i,u}} \\ {{- a}\; f_{i,v}} \\ {a\left( {{u\; f_{i,u}} + {v\; f_{i,v}}} \right)} \\ {{v\; f_{i,u}} - {u\; f_{i,v}}} \\ {{{- \left( {1 + u^{2}} \right)}f_{i,u}} - {u\; v\; f_{i,v}}} \\ {{u\; v\; f_{i,u}} + {\left( {1 + v^{2}} \right)f_{{i,v}\;}}} \end{pmatrix}}{a = \frac{1}{z_{i}}}} & \left( {{Eq}.\mspace{14mu} 17} \right) \end{matrix}$

In an embodiment of the present technology, when the depth is known, one can match the depth of the two frames instead of pixel intensity because when the depth is known, the 3D coordinates of the pixel point are also known. By treating the 3D coordinates in the image capturing device-attached system as a vector function of the 2D pixel coordinates: (x _(i)(u _(i))−δx _(c))δR=x _(j)(u _(j)),  (Eq. 18) one can use a cost function which is the square of the 3D distance between frame f_(i) and frame f_(j): ∫∥(x _(i)(u)−δx _(c))δR−x _(j)(δP(u))∥² du  (Eq. 19) Another possibility would be to use the square of the difference of z component between these two.

This algorithm can be easily extended to handle color images. For example, for RGB images, frame f=(f^(y), f^(g), f^(b)) is a row vector, and D=(D^(y), D^(g), D^(b)) is a 6×3 matrix with D^(y), D^(g), D^(b) each as a 6×1 column vector.

Similar to the algorithm optimization for pixel intensity, the Jacobian calculation is done on x_(i) side, and the transformation is performed on x_(j) side. The column vector D is now replaced by a 6×3 matrix D′ because there are three components in a set of 3D coordinates:

$\begin{matrix} {D^{\prime} = {{{\nabla x_{i}}\frac{{\partial\delta}\; P}{\partial\xi}} - {\begin{pmatrix} {- l_{3 \times 3}} \\ \begin{pmatrix} y_{i} & {- x_{i}} & 0 \\ {- z_{i}} & 0 & x_{i} \\ 0 & z_{i} & {- y_{i}} \end{pmatrix} \end{pmatrix}.}}} & \left( {{Eq}.\mspace{14mu} 20} \right) \end{matrix}$

In this embodiment of the present technology, the image processing algorithm 25 can be implemented by using the following loop routine:

1. Initialize ξ

2. Construct image pyramids of z_(i) and z_(j) if not already available

3. From top to bottom for each level of the pyramid

-   -   3.1 initialize D′ at frame f_(i)     -   3.2 calculate δP from ξ, perform transformation on x_(j):         x _(j)(u)         x′ _(j)(u)=x _(j)(δP(u))δR ^(T) +δx _(c)     -   3.3 calculate dξ; from x_(i), x′_(j),         dξ=∫(x _(i)(u)−x′ _(j)(u))D′ ^(T) du/∫D′D′ ^(T) du     -   3.4 update ξ, dξ         ξ     -   3.5 if dξ is small enough or maximum iteration reached then         exit, otherwise loop back to step 3.2.

In an embodiment of the present technology, one may use a combination of the pixel intensity matching cost function and the depth matching cost function ∫(λ|f _(i)(u)−f _(j)(δP(u))|²+(1−λ)∥(x _(i)(u)−δx _(c))δR−x _(j)(δP(u))∥)² du  (Eq. 21) λε[0, 1] is a weighting factor to be adjusted according to how well the optical flow assumption is held, the quality of the optical image, and the quality of the depth image. The incremental change in each iteration is dξ=∫λ(f _(i)(u)−f′ _(j)(u))D ^(T)+(1−λ)(x _(i)(u)−x′ _(j)(u))D′ ^(T) du/∫λDD ^(T)+(1−λ)D′D′ ^(T) du  (Eq. 22)

In an embodiment of the present technology, the relation between the delta motion and the total motion of f_(i) and f_(i+1) is as follows: R _(i+1) =R ₁ δR _(i→i+1) x _(ci+1) =x _(ci) +δx _(ci→i+1) R _(i) ^(T).  (Eqs. 23) If the loop exits on maximum iteration without converging on ξ between f_(i) and f_(i+1), one may choose to replace f_(i) with f_(i−1), find out the movement between f_(i−1) and f_(i+1) instead, or one may choose to proceed between f_(i) and f_(i+2) and mark the result between f_(i) and f_(i+1), as unreliable.

The depth information for each pixel in f_(i) is needed to 1) transform f_(j)(u)

f′_(j)(u)=f_(j) (δP(u)) and 2) to compute Jacobian at f_(i). Depth information may arrive in different forms.

In an embodiment of the present technology, the scene is relatively flat and can be described by a few (much less than the pixel numbers in the frame) pre-surveyed points, in the stationary reference system. If this is the case, the pre-surveyed points expressed in the stationary reference system need to be transformed into the frame f_(i)'s reference system z(x,y)

z_(i) (u_(i)). These points then will be used as the reference points to find out the depth for each pixel point in f_(i) by triangular interpolation. In a triangular interpolation a point in the triangle is expressed as a combination of three vertices of the triangle. The three combination coefficients need to be adjusted when switching between the 3D reference system and projected 2D reference system, according to the depths of three vertices.

In an embodiment of the present technology, a few (much less than the pixel numbers in the frame) depth points are obtained along with each frame in image capturing device-attached system, such as from point lasers attached to the image capturing device, or matching feature points from a stereo camera rig. If this is the case, the laser point depth measurements come with each frame. They and points from previous frames are put into three categories:

1) Settling points: laser point depth measurements come with frame f_(i+1). They are used only if depth matching is employed.

2) Active points: laser point depth measurements come with frame f_(i), and laser point depth measurements come with earlier frames which have not moved out of either frames and have been transformed into frame f_(i)'s reference system. These points are put in Delaunay Triangulation. The Delaunay vertex points are used as reference points to calculate pixel depth of by triangular interpolation. 3) Retired points: These points are from previous frame which have moved out of f_(i) and f₊₁. These points are saved to form a depth map of the scene if desired.

In an embodiment of the present technology, a grid of depth points is available with each frame, in image capturing device-attached reference system, with the same resolution as or comparable resolution to the video frame. In this case, depth measurements obtained with frame f_(i) can be used directly if the resolution is the same, or can be interpolated if the resolution is lower. Depth measurements obtained with f_(i) and f_(i+1) can be used in depth matching directly or after interpolation.

In an embodiment of the present technology FIG. 2 is a flow chart 50 of a method of image-tracking by using the device 22 of FIG. 1, wherein the depth data of the scene 20 is obtained by pre-surveying the scene.

In this embodiment of the present technology, the method of image-tracking comprises two steps: (step 54) performing an image-capture of the scene 20 (of FIG. 1) by using an image capturing device; and (step 62) tracking movement of the image capturing device by analyzing a set of images obtained in the step 54.

In an embodiment of the present technology, step 54 of performing an image-capture of the scene 20 is performed in real time by using the image capturing device 22 (of FIG. 1)—step 56.

In an embodiment of the present technology, step 54 is performed by pre-recording the scene 20 by using the image capturing device 22—step 58.

In an embodiment of the present technology, step 54 further comprises obtaining a set of depth data of the scene 20 by pre-surveying the scene—step 60.

As was disclosed above, the image capturing device is selected from the group consisting of: {a digital camera; a digital video camera; a digital camcorder; a stereo digital camera; a stereo video camera; a motion picture camera; and a television camera}.

In an embodiment of the present technology, step 62 of tracking movement of the image capturing device by analyzing the set of images obtained in the step 54 further comprises the step 64 of performing a rigid global transformation of the set of captured image data and the set of scene depth data into a set of 6-coordinate data; wherein the set of 6-coordinate data represents movement of the image capturing device 22 (of FIG. 1).

In an embodiment of the present technology, FIG. 3 illustrates a flow chart 100 of a method of image-tracking, wherein the depth data of the scene is obtained by using a range measurement device 14.

In an embodiment of the present technology, the flow chart 100 of a method of image-tracking further comprises step 104 of performing an image-capture of a scene by using an image capturing device.

In an embodiment of the present technology, step 104 can be implemented by performing the image-capture of the scene in real time by using the image capturing device—step 106.

In an embodiment of the present technology, step 104 can be implemented by performing the step 108 of performing an image-recording of the scene by using the image capturing device.

In an embodiment of the present technology, the flow chart 100 of a method of image-tracking further comprises the step 110 of obtaining a set of scene depth data by using a range measurement device selected from the group consisting of: {a point laser beam; a sonar; a radar; a laser scanner; and a depth camera}.

In an embodiment of the present technology, the step 110 is implemented by determining the set of scene depth data in an image capturing device-attached 3D-reference system by using a K-point range measurement system attached to the image capturing device—step 112.

In an embodiment of the present technology, the step 110 is implemented by determining the depth of the object point directly for at least one image point of the object point by using an M-point range measurement system attached to the image capturing device, wherein the integer number M of depth measurements of the scene is substantially equal to the number of pixels in the frame—step 114.

In an embodiment of the present technology, the step 110 is implemented by determining the set of scene depth data in a image capturing device-attached 3D reference system by using a feature-point range measurement system attached to the image capturing device—step 116.

Finally, in an embodiment of the present technology, the flow chart 100 of a method of image-tracking further comprises the step 118 of tracking movement of the image capturing device by analyzing the set of images.

In an embodiment of the present technology, the step 118 is performed by performing a rigid global transformation of the set of captured images data and the set of scene depth data into a set of 6-coordinate data; wherein the set of 6-coordinate data represents movement of the image capturing device—step 120.

FIGS. 4, 5, 6, and 7 illustrate the sample results of the image-based tracking using the apparatus 22 of FIG. 1. More specifically, FIG. 2 depicts diagram 140 illustrating the image capturing device image of the scene 20 in the sensor plane 16.

FIG. 5 shows a diagram 150 illustrating the image capturing device 2D motion calculated by using the algorithm 25 of FIG. 1 as was fully disclosed above.

FIG. 6 depicts a diagram 160 illustrating the image capturing device height motion calculated by using the algorithm 25 of FIG. 1 as was fully disclosed above.

FIG. 7 shows a diagram 170 illustrating the image capturing device total rotation angles (yaw 172, pitch 174 and roll 176) calculated by using the algorithm 25 of FIG. 1 as was fully disclosed above.

The above discussion has set forth the operation of various exemplary systems and devices, as well as various embodiments pertaining to exemplary methods of operating such systems and devices. In various embodiments, one or more steps of a method of implementation are carried out by a processor under the control of computer-readable and computer-executable instructions. Thus, in some embodiments, these methods are implemented via a computer.

In an embodiment, the computer-readable and computer-executable instructions may reside on computer useable/readable media.

Therefore, one or more operations of various embodiments may be controlled or implemented using computer-executable instructions, such as program modules, being executed by a computer. Generally, program modules include routines, programs, objects, components, data structures, etc., that perform particular tasks or implement particular abstract data types. In addition, the present technology may also be practiced in distributed computing environments where tasks are performed by remote processing devices that are linked through a communications network. In a distributed computing environment, program modules may be located in both local and remote computer-storage media including memory-storage devices.

Although specific steps of exemplary methods of implementation are disclosed herein, these steps are examples of steps that may be performed in accordance with various exemplary embodiments. That is, embodiments disclosed herein are well suited to performing various other steps or variations of the steps recited. Moreover, the steps disclosed herein may be performed in an order different than presented, and not all of the steps are necessarily performed in a particular embodiment.

Although various electronic and software based systems are discussed herein, these systems are merely examples of environments that might be utilized, and are not intended to suggest any limitation as to the scope of use or functionality of the present technology. Neither should such systems be interpreted as having any dependency or relation to any one or combination of components or functions illustrated in the disclosed examples.

Although the subject matter has been described in a language specific to structural features and/or methodological acts, the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as exemplary forms of implementing the claims. 

1. A method of image-tracking comprising: (A) performing an image-capture of a scene by using an image capturing device; (B) generating a set of captured image data and a set of scene depth data; and (B1) performing a rigid global transformation of said set of captured image data and said set of scene depth data into a set of 6-coordinate data; wherein said set of 6-coordinate data represents movement of said image capturing device.
 2. The method of claim 1, wherein said step (B1) further comprises: (B1, 1) using a mapping function of said image capturing device to map for at least one i-th frame 3D coordinates of at least one object point in the reference system attached to said image capturing device, into 2D pixel coordinates of an image point on said image capturing device sensor plane in a 2D reference coordinate system; i being an integer.
 3. The method of claim 2, wherein said step (B1, 1) further comprises: (B1, 1, 1) selecting said mapping function of said image capturing device from the group consisting of: {a mapping function of regular rectilinear lenses; a mapping function of fisheye lenses; and a mapping function of custom-calibrated lenses}.
 4. The method of claim 1, wherein said step (B1) further comprises: (B1, 2) obtaining a reverse of said mapping function; wherein said reverse of said mapping function is configured to map, for at least one i-th frame, 2D pixel coordinates of at least one image point on said image capturing device sensor plane in a 2D reference coordinate system, into 3D coordinates of at least one object point in the reference system attached to said image capturing device.
 5. The method of claim 1, wherein said step (B1) further comprises: (B1, 3) obtaining 3D depth coordinates of said at least one object point by using said pre-surveyed data of said scene.
 6. The method of claim 1, wherein said step (B1) further comprises: (B1, 4) extracting a 6-vector describing said movement of said image capturing device from a relationship between two sequential frames: i-th frame and k-th frame, wherein at least one object point produces at least two pixels of substantially the same intensity in said two sequential frames.
 7. The method of claim 6 further comprising: (B1, 4, 1) optimizing said 6-vector describing the movement of said image capturing device.
 8. The method of claim 6 further comprising: (B1, 4, 2) optimizing said 6-vector describing the movement of said image capturing device by solving a nonlinear least-squares problem for said relationship between said two sequential frames.
 9. The method of claim 6 further comprising: (B1, 4, 3) optimizing a (6−n)-vector describing an n-dimensionally restricted movement of said image capturing device by optimizing said relationship between said two sequential frames; wherein integer n is less than
 6. 10. The method of claim 1, wherein said step (B1) further comprises: (B1, 5) extracting a 6-vector describing said movement of said image capturing device from a relationship between said two sequential frames: i-th frame and k-th frame by matching the depth data for at least two pixels: a first said pixel and a second said pixel; wherein said first pixel is located in said i-th frame, and wherein said second pixel is located in said k-th frame.
 11. The method of claim 10 further comprising: (B1, 5, 1) optimizing said 6-vector describing the movement of said image capturing device.
 12. The method of claim 10 further comprising: (B1, 5, 2) optimizing said 6-vector describing the movement of said image capturing device by solving a nonlinear least-squares problem for said relationship between said two sequential frames.
 13. The method of claim 10 further comprising: (B1, 5, 3) optimizing a (6−n)-vector describing an n-dimensionally restricted movement of said image capturing device by optimizing said relationship between said two sequential frames; wherein integer n is less than
 6. 14. The method of claim 1, wherein said step (B1) further comprises: (B1, 6) extracting a 6-vector describing said movement of said image capturing device from a relationship between two sequential frames: i-th frame and k-th frame by matching the depth data for at least two pixels: a first pixel and a second pixel; wherein said first pixel is located in said i-th frame, and wherein said second pixel is located in said k-th frame, and by matching at least two pixels having substantially the same intensity in said two sequential frames.
 15. The method of claim 14 further comprising: (B1, 6, 1) optimizing said 6-vector describing the movement of said image capturing device.
 16. The method of claim 14 further comprising: (B1, 6, 2) optimizing said 6-vector describing the movement of said image capturing device by solving a nonlinear least-squares problem for said relationship between said two sequential frames.
 17. The method of claim 14 further comprising: (B1, 6, 3) optimizing a (6−n)-vector describing an n-dimensionally restricted movement of said image capturing device by optimizing said relationship between said two sequential frames; wherein integer n is less than
 6. 18. A method of image-tracking comprising: (A) performing an image-capture of a scene by using an image capturing device; (B1) determining said set of scene depth data in an image capturing device—attached 3D reference system by using a K-point range measurement system attached to said image capturing device, wherein said set of scene depth data comprises an integer K-point set of 3D depth measurements of said scene; and wherein a 3D depth coordinate of at least one object point associated with a 2D image point of said 3D object point is obtained by interpolation of said K-point set of 3D depth measurements of said scene to obtain an optimum depth measurement for at least one image point of at least one said object point; and wherein said integer K is substantially less than number of pixels in said frame; and (C) tracking movement of said image capturing device by analyzing said set of images.
 19. A method of image-tracking comprising: (A) performing an image-capture of a scene by using an image capturing device; (B2) determining said depth of said object point directly for at least one image point of said object point by using an M-point range measurement system attached to said image capturing device, wherein said integer number M of depth measurements of said scene is substantially equal to the number of pixels in said frame; and (C) tracking movement of said image capturing device by analyzing said set of images.
 20. A method of image-tracking comprising: (A) performing an image-capture of a scene by using an image capturing device; (B3) determining said set of scene depth data in an image capturing device—attached 3D reference system by using a feature-point range measurement system attached to said image capturing device, wherein said scene comprises a set of integer K feature object points; wherein said feature-point range measurement system obtains a K set of 3D depth measurements of said K feature object points in said scene; and wherein a 3D depth coordinate of at least one object point associated with a 2D image point of said 3D object point is obtained by interpolation of said K-point set of 3D depth measurements of said scene to obtain an optimum depth measurement for at least one image point of at least one said object point; and wherein said integer K is substantially less than the number of pixels in said frame; and (C) tracking movement of said image capturing device by analyzing said set of images.
 21. A method of image-tracking comprising: (A) performing an image-capture of a scene by using an image capturing device; (B) obtaining a set of scene depth data by using a range measurement device selected from the group consisting of: {a point laser beam; a sonar; a radar; a laser scanner; and a depth camera}; and (C1) performing a rigid global transformation of said set of captured images data and said set of scene depth data into a set of 6-coordinate data; wherein said set of 6-coordinate data represents movement of said image capturing device.
 22. The method of claim 21, wherein said step (C1) further comprises: (C1, 1) using mapping function to map, for at least one i-th frame, 3D coordinates of at least one object point in the reference system attached to said image capturing device, into 2D pixel coordinates of an image point on said image capturing device sensor plane in a 2D reference coordinate system.
 23. The method of claim 22, wherein said step (C1, 1) further comprises: (C1, 1, 1) selecting said mapping function from the group consisting of: {a mapping function of regular rectilinear lenses; a mapping function of fisheye lenses; and a mapping function of custom-calibrated lenses}.
 24. The method of claim 21, wherein said step (C1) further comprises: (C1, 2) obtaining a reverse of said mapping function; said reverse of said mapping function is configured to map, for at least one i-th frame 2D pixel coordinates of at least one image point on said image capturing device sensor plane in a 2D reference coordinate system, into 3D coordinates of at least one object point in the reference system attached to said image capturing device.
 25. The method of claim 21, wherein said step (C1) further comprises: (C1, 3) extracting a 6-vector describing said movement of said image capturing device from a relationship between said two sequential frames: i-th frame and k-th frame, wherein at least one point in said scene produces at least two pixels of substantially the same intensity in said two sequential frames.
 26. The method of claim 25 further comprising: (C1, 3, 1) optimizing said 6-vector describing the movement of said image capturing device.
 27. The method of claim 25 further comprising: (C1, 3, 2) optimizing said 6-vector describing the movement of said image capturing device by solving a nonlinear least-squares problem for said relationship between said two sequential frames.
 28. The method of claim 25 further comprising: (C1, 3, 3) optimizing a (6−n)-vector describing an n-dimensionally restricted movement of said image capturing device by optimizing said relationship between said two sequential frames; wherein integer n is less than
 6. 29. The method of claim 21, wherein said step (C1) further comprises: (C1, 4) extracting a 6-vector describing said movement of said image capturing device from a relationship between said two sequential frames: i-th frame and k-th frame by matching the depth data for at least two pixels: a first said pixel and a second said pixel; wherein said first pixel is located in said i-th frame, and wherein said second pixel is located in said k-th frame.
 30. The method of claim 29 further comprising: (C1, 4, 1) optimizing said 6-vector describing the movement of said image capturing device.
 31. The method of claim 30 further comprising: (C1, 4, 3) optimizing a (6−n)-vector describing an n-dimensionally restricted movement of said image capturing device by optimizing said relationship between said two sequential frames; wherein integer n is less than
 6. 32. The method of claim 29 further comprising: (C1, 4, 2) optimizing said 6-vector describing the movement of said image capturing device by solving a nonlinear least-squares problem for said relationship between said two sequential frames.
 33. The method of claim 21, wherein said step (C1) further comprises: (C1, 5) extracting a 6-vector describing said movement of said image capturing device from a relationship between said two sequential frames: i-th frame and k-th frame by matching the depth data for at least two pixels: a first pixel and a second pixel; wherein said first pixel is located in said i-th frame, and wherein said second pixel is located in said k-th frame, and by matching at least two pixels having substantially the same intensity in said two sequential frames.
 34. The method of claim 33 further comprising: (C1, 5, 1) optimizing said 6-vector describing the movement of said image capturing device.
 35. The method of claim 33 further comprising: (C1, 5, 2) optimizing said 6-vector describing the movement of said image capturing device by solving a nonlinear least-squares problem for said relationship between said two sequential frames.
 36. The method of claim 33 further comprising: (C1, 5, 3) optimizing a (6−n)-vector describing an n-dimensionally restricted movement of said image capturing device by optimizing said relationship between said two sequential frames; wherein integer n is less than
 6. 37. An apparatus for image-tracking comprising: (A) an image capturing device configured to perform an image-capture of a scene; and (B1) a means for performing a rigid global transformation of said set of captured images and said set of scene depth data into a set of 6-coordinate data; wherein said set of 6-coordinate data represents movement of said image capturing device. 